Design and Validation of a Passive Motion Scaling Mechanism Prototype for Microsurgery

Since the advent of the commercial da Vinci surgical system, microsurgical robotic systems have been increasingly investigated. These systems improve the accuracy and dexterity of surgeries using a computerized motion scaling function between a surgeon’s hand and surgical instrument. However, the ma...

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Bibliographic Details
Published inInternational journal of precision engineering and manufacturing Vol. 23; no. 9; pp. 1065 - 1075
Main Authors Choi, Dongeun, Lee, Tae-Hoon, Song, Jae-Bok, Lee, Woosub
Format Journal Article
LanguageEnglish
Published Seoul Korean Society for Precision Engineering 01.09.2022
Springer Nature B.V
Subjects
Actuators
Displacement
Engineering
Industrial and Production Engineering
Materials Science
Microsurgery
Pitch (inclination)
Prototypes
Regular Paper
Scaling
Surgeons
Surgery
Surgical apparatus & instruments
Surgical instruments
Yaw
Passive motion scaling
Microsurgery
Pantograph mechanism
Parallelogram mechanism
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Summary:Since the advent of the commercial da Vinci surgical system, microsurgical robotic systems have been increasingly investigated. These systems improve the accuracy and dexterity of surgeries using a computerized motion scaling function between a surgeon’s hand and surgical instrument. However, the manufacturing process of these systems is expensive owing to the use of multiple sensors, actuators, and controllers. Additionally, certain limitations exist, such as an increase in the size of the operating room to accommodate the robotic system and the absence of tactile force feedback. To address these problems, we propose a passive motion scaling mechanism for microsurgery. Based on the pantograph mechanism, we downscale the linear displacement of the surgeon’s hand and transfer it to the surgical instrument. Furthermore, the rotational displacement of the surgeon’s hand in an actual surgery is transmitted to the surgical instrument on a 1:1 scale by applying a parallelogram mechanism. We designed and fabricated a prototype capable of transmitting linear and rotational displacements (pitch and yaw) of the surgeon’s hand with three degrees of freedom (DOFs) and two DOFs, respectively, by combining the two mechanisms. The obtained experimental results verify the motion scaling function of the developed prototype.
ISSN:2234-7593
2005-4602
DOI:10.1007/s12541-022-00624-3